PEPPeR, a Platform for Experimental Proteomic Pattern Recognition

Jaffe, Jacob D.; Mani, D. R.; Leptos, Kyriacos C.; Church, George M.; Gillette, Michael A.; Carr, Steven A.

doi:10.1074/mcp.m600222-mcp200

Cited by 134 publications

(147 citation statements)

References 42 publications

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“…The workflow described here contains functionality similar to traditional AMT 5 and also PEPPeR, 8 but msInspect/AMT was designed to provide a highly flexible approach to combining data from different experimental and biological sources. For example, our AMT matching procedures described above were designed to function when only a potentially small number of peptide locations from an LC-MS experiment are present in the AMT database, such as may be the case when interrogating across dissimilar biospecimen types.…”

Section: Discussionmentioning

confidence: 99%

“…7 More recently, novel commercial instrumentation such as the LTQ-FT and Orbitrap, and the Q-TOF, have allowed simultaneous acquisition of both high-resolution LC-MS and LC-MS/MS data in a single experiment. Jaffe et al recently described a workflow incorporated in PEPPeR (Platform for Experimental Proteomic Pattern Recognition) 8 that combines peptide locations with amino acid sequences acquired from a series of related runs with these platforms. This workflow is related to the classic AMT approach in that it combines LC-MS and LC-MS/MS data, but because it takes advantage of embedded MS/MS data, it is useful for combining data across a series of related experiments and does not involve the use of externally derived data sources.…”

Section: Introductionmentioning

confidence: 99%

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A Platform for Accurate Mass and Time Analyses of Mass Spectrometry Data

et al. 2007

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We describe an integrated suite of algorithms and software for general accurate mass and time (AMT) tagging data analysis of mass spectrometry data. The AMT approach combines identifications from liquid chromatography (LC) tandem mass spectrometry (MS/MS) data with peptide accurate mass and retention time locations from high-resolution LC-MS data. Our workflow includes the traditional AMT approach, in which MS/MS identifications are located in external databases, as well as methods based on more recent hybrid instruments such as the LTQ-FT or Orbitrap, where MS/MS identifications are embedded with the MS data. We demonstrate our AMT workflow's utility for general data synthesis by combining data from two dissimilar biospecimens. Specifically, we demonstrate its use relevant to serum biomarker discovery by identifying which peptides sequenced by MS/MS analysis of tumor tissue may also be present in the plasma of tumor-bearing and control mice. The analysis workflow, referred to as msInspect/AMT, extends and combines existing open-source platforms for LC-MS/MS (CPAS) and LC-MS (msInspect) data analysis and is available in an unrestricted open-source distribution.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A Platform for Accurate Mass and Time Analyses of Mass Spectrometry Data

et al. 2007

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“…To quantify the sensitivity of the COFRADIC methodology, i.e., the ability to detect low-abundant as well as high-abundant peptide peaks, we used the dynamic range expressed in decibels (dB), which was calculated as: 10 log 10 P max P min (8) with P max and P min denoting the maximum and minimum peptide abundance measured in an experiment, obtained via Eqn (5). A dynamic range of 37 dB was found for all COFRADIC replicates.…”

Section: Human Blood Samplementioning

confidence: 99%

“…First, available software packages, such as, e.g., SpecArray, [3] PEPPeR, [5] and SuperHirn, [6] which can be used to analyze, combine, and interpret data from high-dimensional LC and MS as an automated procedure, are based on datadriven methods or image processing methods to extract the peptide features from LC-MS. We present an approach that does not operate on the LC-MS image and we argue that the prior processing of LC-MS data can be split into two parts. In the first part, the MS-scans are processed separately, in order to extract peptide features on the basis of prior biological knowledge about the peptide's isotopic distribution, and not on a data-driven method.…”

Section: Introductionmentioning

confidence: 99%

A strategy for the prior processing of high‐resolution mass spectral data obtained from high‐dimensional combined fractional diagonal chromatography

Valkenborg

Thomas²,

Krols³

et al. 2008

J. Mass Spectrom.

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Combined fractional diagonal chromatography (COFRADIC) is a novel suite of gel-free technologies for the identification of biomarkers in complex peptide mixtures. For this purpose, reversed-phase high performance liquid chromatography (HPLC) technology and, in this case, matrix assisted laser desorption /ionization-time of flight (MALDI-TOF) mass spectrometers are extensively used. The particular characteristic of COFRADIC mass spectrometry data is the high number of chromatographic fractions, over which a peptide can be scattered. This can obstruct the quantification of the peptide abundance in the biological sample, which is required for statistical analysis. On the other hand, because of the superior peptide sorting properties of the methodology, the mass spectra become less crowded. Consequently, each peptide appears in a mass spectrum as a series of peaks with peak heights proportional to the probability of occurrence of the isotopic variants of the peptide. In this manuscript, we propose an analysis strategy concerned with the preprocessing of COFRADIC mass spectra prior to a downstream statistical analysis. The preprocessing algorithm produces for each mass spectrum a peptide list by exploiting the characteristic features that should be associated with peaks corresponding to an isotopically resolved cluster of peptide peaks. This reduction step is necessary to facilitate the clustering used in a next step to assemble the validated monoisotopic peptide peaks found over several fractions into a single peptide abundance. To assess the performance of the algorithm, two technical experiments were conducted. The proposed strategy is memory and computationally efficient.

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“…In general, these computational methods can be divided into two groups. In the first group, spectral features (typically isotopic clusters indicating a peptide) are detected first and then statistically compared [25][26][27][28][29]. Alternatively, the second group applies statistics first so that only differential features are detected from the extracted ion chromatograms [30][31][32][33].…”

Section: Differential Ms Quantitationmentioning

confidence: 99%

Quantitative strategies to fuel the merger of discovery and hypothesis-driven shotgun proteomics

Kline¹,

Finney²,

Wu³

2009

Briefings in Functional Genomics and Proteomics

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The ultimate goal of most shotgun proteomic pipelines is the discovery of novel biomarkers to direct the development of quantitative diagnostics for the detection and treatment of disease. Differential comparisons of biological samples identify candidate peptides that can serve as proxys of candidate proteins. While these discovery approaches are robust and fairly comprehensive, they have relatively low throughput. When merged with targeted mass spectrometry, this pipeline can fuel hypothesis-driven studies and the development of novel diagnostics and therapeutics.

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PEPPeR, a Platform for Experimental Proteomic Pattern Recognition

Cited by 134 publications

References 42 publications

A Platform for Accurate Mass and Time Analyses of Mass Spectrometry Data

A Platform for Accurate Mass and Time Analyses of Mass Spectrometry Data

A strategy for the prior processing of high‐resolution mass spectral data obtained from high‐dimensional combined fractional diagonal chromatography

Quantitative strategies to fuel the merger of discovery and hypothesis-driven shotgun proteomics

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